Your search keyword '"Jean A. Laissue"' showing total 4 results

1. Synchrotron X-ray interlaced microbeams suppress paroxysmal oscillations in neuronal networks initiating generalized epilepsy

Author

Benoît Pouyatos, Raphaël Serduc, Mathilde Chipaux, Tanguy Chabrol, Elke Bräuer-Krisch, Christian Nemoz, Hervé Mathieu, Olivier David, Luc Renaud, Yolanda Prezado, Jean Albert Laissue, François Estève, Stéphane Charpier, and Antoine Depaulis

Subjects

Epilepsy, Animal model, Spike-wave discharges, Radiotherapy, Synchrotron X-ray microbeams, Intracellular recordings, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Radiotherapy has shown some efficacy for epilepsies but the insufficient confinement of the radiation dose to the pathological target reduces its indications. Synchrotron-generated X-rays overcome this limitation and allow the delivery of focalized radiation doses to discrete brain volumes via interlaced arrays of microbeams (IntMRT). Here, we used IntMRT to target brain structures involved in seizure generation in a rat model of absence epilepsy (GAERS). We addressed the issue of whether and how synchrotron radiotherapeutic treatment suppresses epileptic activities in neuronal networks. IntMRT was used to target the somatosensory cortex (S1Cx), a region involved in seizure generation in the GAERS. The antiepileptic mechanisms were investigated by recording multisite local-field potentials and the intracellular activity of irradiated S1Cx pyramidal neurons in vivo. MRI and histopathological images displayed precise and sharp dose deposition and revealed no impairment of surrounding tissues. Local-field potentials from behaving animals demonstrated a quasi-total abolition of epileptiform activities within the target. The irradiated S1Cx was unable to initiate seizures, whereas neighboring non-irradiated cortical and thalamic regions could still produce pathological oscillations. In vivo intracellular recordings showed that irradiated pyramidal neurons were strongly hyperpolarized and displayed a decreased excitability and a reduction of spontaneous synaptic activities. These functional alterations explain the suppression of large-scale synchronization within irradiated cortical networks. Our work provides the first post-irradiation electrophysiological recordings of individual neurons. Altogether, our data are a critical step towards understanding how X-ray radiation impacts neuronal physiology and epileptogenic processes.

Published

2013

2. Effects of Synchrotron X-Ray Micro-beam Irradiation on Normal Mouse Ear Pinnae

Author

Mattia Donzelli, Marine Potez, John W. Hopewell, Jeannine Wagner, Jean A. Laissue, Valentin Djonov, Audrey Bouchet, Elke Bräuer-Krisch, Institute of Anatomy, University of Berne, and European Synchrotron Radiation Facility (ESRF)

Subjects

Cancer Research, Pathology, medicine.medical_specialty, BRAIN-TUMORS, Time Factors, 610 Medicine & health, X-Ray Therapy, Sarcomere, 030218 nuclear medicine & medical imaging, law.invention, 03 medical and health sciences, Mice, 0302 clinical medicine, VESSELS, law, Hair cycle, RADIATION-THERAPY, medicine, Animals, Radiology, Nuclear Medicine and imaging, DAMAGE, [PHYS]Physics [physics], Radiation, business.industry, Cartilage, Dose-Response Relationship, Radiation, Ear, QUANTIFICATION, EFFICACY, 3. Good health, Mice, Inbred C57BL, Dose–response relationship, Radiation Injuries, Experimental, medicine.anatomical_structure, Lymphatic system, Oncology, TISSUE, Apoptosis, Organ Specificity, WIGGLER, 030220 oncology & carcinogenesis, Female, Electron microscope, HAIR CYCLE, business, SKIN, Synchrotrons, Blood vessel

Abstract

International audience; Purpose: To analyze the effects of micro-beam irradiation (MBI) on the normal tissues of the mouse ear.Methods and Materials: Normal mouse ears are a unique model, which in addition to skin contain striated muscles, cartilage, blood and lymphatic vessels, and few hair follicles. This renders the mouse ear an excellent model for complex tissue studies. The ears of C57BL6 mice were exposed to MBI (50-mu m-wide micro-beams, spaced 200 mu m between centers) with peak entrance doses of 200, 400, or 800 Gy (at ultra-high dose rates). Tissue samples were examined histopathologically, with conventional light and electron microscopy, at 2, 7, 15, 30, and 240 days after irradiation (dpi). Sham-irradiated animals acted as controls.Results: Only an entrance dose of 800 Gy caused a significant increase in the thickness of both epidermal and dermal ear compartments seen from 15 to 30 dpi; the number of sebaceous glands was significantly reduced by 30 dpi. The numbers of apoptotic bodies and infiltrating leukocytes peaked between 15 and 30 dpi. Lymphatic vessels were prominently enlarged at 15 up to 240 dpi. Sarcomere lesions in striated muscle were observed after all doses, starting from 2 dpi; scar tissue within individual beam paths remained visible up to 240 dpi. Cartilage and blood vessel changes remained histologically inconspicuous.Conclusions: Normal tissues such as skin, cartilage, and blood and lymphatic vessels are highly tolerant to MBI after entrance doses up to 400 Gy. The striated muscles appeared to be the most sensitive to MBI. Those findings should be taken into consideration in future micro-beam radiation therapy treatment schedules. (C) 2018 The Authors. Published by Elsevier Inc. This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/).

Published

2018

3. Use of synchrotron medical microbeam irradiation to investigate radiation-induced bystander and abscopal effects in vivo

Author

Hans Blattmann, Carmel Mothersill, Cristian Fernandez-Palomo, Elke Bräuer-Krisch, Jean A. Laissue, Elisabeth Schültke, Dusan Vukmirovic, and Colin Seymour

Subjects

Male, Technology Assessment, Biomedical, Radiation-induced bystander effects, Cell Survival, medicine.medical_treatment, Biophysics, General Physics and Astronomy, 610 Medicine & health, Physics and Astronomy(all), Radiotherapy, High-Energy, In vivo, Cell Line, Tumor, Glioma, Calcium flux, 540 Chemistry, Bystander effect, Animals, Medicine, Radiology, Nuclear Medicine and imaging, Synchrotron microbeam radiation, Evidence-Based Medicine, Brain Neoplasms, business.industry, Dose fractionation, Abscopal effect, Radiotherapy Dosage, Microbeam irradiation, Bystander Effect, Equipment Design, General Medicine, medicine.disease, Fischer rats, Rats, Radiation therapy, Treatment Outcome, Radiology Nuclear Medicine and imaging, Cancer research, 570 Life sciences, biology, Dose Fractionation, Radiation, business, Nuclear medicine, Synchrotrons, F98 glioma

Abstract

The question of whether bystander and abscopal effects are the same is unclear. Our experimental system enables us to address this question by allowing irradiated organisms to partner with unexposed individuals. Organs from both animals and appropriate sham and scatter dose controls are tested for expression of several endpoints such as calcium flux, role of 5HT, reporter assay cell death and proteomic profile. The results show that membrane related functions of calcium and 5HT are critical for true bystander effect expression. Our original inter-animal experiments used fish species whole body irradiated with low doses of X-rays, which prevented us from addressing the abscopal effect question. Data which are much more relevant in radiotherapy are now available for rats which received high dose local irradiation to the implanted right brain glioma. The data were generated using quasi-parallel microbeams at the biomedical beamline at the European Synchrotron Radiation Facility in Grenoble France. This means we can directly compare abscopal and “true” bystander effects in a rodent tumour model. Analysis of right brain hemisphere, left brain and urinary bladder in the directly irradiated animals and their unirradiated partners strongly suggests that bystander effects (in partner animals) are not the same as abscopal effects (in the irradiated animal). Furthermore, the presence of a tumour in the right brain alters the magnitude of both abscopal and bystander effects in the tissues from the directly irradiated animal and in the unirradiated partners which did not contain tumours, meaning the type of signal was different.

Published

2015

4. Applications of synchrotron X-rays to radiotherapy

Author

J. Stepanek, A. Bravin, Hans Blattmann, Jean A. Laissue, G. Le Duc, Elke Bräuer-Krisch, D. N. Slatkin, M. Di Michiel, J.-O. Gebbers, Valentin Djonov, W. Burkard, Blattmann, H, Gebbers, J, Brauer-Krisch, E, Bravin, A, Le Duc, G, Burkard, W, Di Michiel, M, Djonov, V, Slatkin, D, Stepanek, J, and Laissue, J

Subjects

Nuclear and High Energy Physics, medicine.medical_specialty, medicine.medical_treatment, FIS/07 - FISICA APPLICATA (A BENI CULTURALI, AMBIENTALI, BIOLOGIA E MEDICINA), Synchrotron X-ray, Radiation, Radiosurgery, Tomotherapy, Collimated light, law.invention, law, Photon activation therapy, medicine, Medical physics, Irradiation, Instrumentation, Physics, CAM, business.industry, Bremsstrahlung, Synchrotron, Radiation therapy, Nuclear medicine, business, Microbeam radiation therapy

Abstract

Radiotherapy is among the most useful treatments of cancer. Penetrating radiation (ionizing particles or bremsstrahlung photons) is aimed toward the tumor-bearing target, gradually delivering as high radiation to it as is usefully suppressive of tumor growth, yet tolerated by normal vital tissues inevitably irradiated with the tumor. The high collimation and dose rate of synchrotron X-ray beams, even when monochromatized, favor radiotherapy. Photon activation therapy, tomotherapy, microbeam radiation therapy, and radiosurgery mediated by synchrotron wigglers are conceptually promising for difficult tumors. Radiotherapy of malignant brain tumors in rats has been encouraging, but suitable beam lines exist at only a few research facilities and much basic work must be done before the promise of synchrotron-based radiotherapy can be realized clinically.

Published

2005